Air modulated drive means



Oct. 20, 1964 G. L. N. MEYER AIR MODULATED DRIVE MEANS '7 Sheets-Sheet 1 Filed April 30 1962 INVENTOR. Gaoaee LNMEYER )Wwmd ATTORNEY 7 Sheets-Sheet 2 Oct. 20, 1964 G. 1.. N. MEYER AIR MODULATED DRIVE MEANS Filed April 30, 1962 m m k j m 3 l m H F 9 J W B .i w M2 i. A 3%; k a H 05 NM: f W 1. qN. 0N WNW r jdm .N. 7w. 2 2 I l.

Oct. 20, 1964 G. L. N. MEYER AIR MODULATED DRIVE MEANS '7 Sheets-Sheet 5 Filed April 30 1962 GEORGE LN. MEYER :0. WM ATTORNEY Oct. 20, 1964 G. L. N. MEYER 3,153,478

AIR MODULATED DRIVE MEANS Filed April 30, 1962 7 Sheets-Sheet 4 FIG-5 1 l E 82 1 84 K 84 86 5 as 5 M 8o 1 M J W \E 1* W M J A" "1 INVENTOR. i l; Gsoaee L.N.Mavea dmA ifl/ZwAM ATTORNEY Oct. 20, 1964 G. N. MEYER 3,153,478

AIR MODULA'IED DRIVE MEANS '7 Sheets-Sheet 5 Filed April 30, 1962 INVENTOR. GEORGE LN. MEYER F ma. 9 BY I ATTORNEY Oct. 20, 1964 G. L. N. MEYER 3,153,478

AIR MODULATED DRIVE MEANS Filed April 30, 1962 7 Sheets-Sheet 6 F'na.

Fae. l2

INVENTOR. Geoaee L.N. MEYER A-r'roauav Oct. 20, 1964 e. L. N. MEYER AIR MODULATED DRIVE MEANS 7 Sheets-Sheet 7 Filed April 30, 1962 R Rn OF. T WM 3 W L e m o E 6 C G 6 G GI ma mi zgz aim 01W ATTORNEY capacity of thefiller is set slightly put of the cleaner inspector in the conveyor line and filler creates several constant flow of the rotation of theturretand the bottle flow from the cleaner.

variations in the momentum of the bottles at the turret at thefturretby the bottle 1 flow will. tend to cause a to the filler. A further consideration is the maintenance slant liowfof bottles through nf variations in the momentum turret.

to some degree to hecomes more and more is positioned tothe filler. readily appreciated that it is always Patented o'e 2o, '1964 3,1 78 7 AIR. MonULAT p DRIVE MEANS and LN; s n, Mummies wot, assignorto Geo. nmw m LMeyerMnn acturing C0,,- dolly 5011 of Wisconsin Filed Apr. 30, 1962, Scr. No. 191,179

I 12 Claims. (Cl. 198-409) This invention r'clates generally to a motor drive and control means and'rnore particularly to aflmotor drive and control for a hottle inspection apparatus adapted for inspecting bottles "carried on a conveyor from a bottle cleaner to a bottle filler. Due to the inherent type thatthe bottlc'handling capacityof theconveyor I design characteristics of a bottle. I cleaner and the desirability of providing a flow o bottles. n lth fi i if e'cessarvin sw ms o obvious modifications of the single I the. drawings, in which:

exceeds both the output of the washer and the" input .7

capacity of the filler.

Under normal operating conditions involving onlya bottle cleaner and filler, the input ig i e he o I to prevent excessive back-accumulation at the filler due to the greater capacity of the con- ;Some baclgaocumulation is desirable, however, to insure a constant supply'ot bottles at the tiller.

The interposing of a third machine such as a bottle between the'bottle cleaner problem involves the synchronization of the bottle flow into the inspector with the rotation of the inspeotorindexing member and the maintenance of a substantially starwheel turret to entry from the conveyor through then back onto the conve or the bottles in an arcuate' path the inspection station and (if not rejected). Unless the inflow of bottles is properly-synchronized, jamming and clashing will occur as the bottles are engaged by the turret. The problem is particularly ditlicult due to frequentzirregula'rities in the variable torque produced variable inspector throughput of a minimum turret speed'to facilitate proper bottle inspection; Amaximum turret speed must also he 'rnaintained to prevent excessive back-accumulation .atthe filler. It is one object of this invention, therefore, to

{provide a means for automatically maintaining synv chronizatlon between the turret and-the flow of bottles intothe inspector and for'tproviding a substantially con the inspector irrespective of the bottlesat'the A 'further object is to provide the above characteristics without allowing theiturre't to exceed apredetermined maximum speed while'a't the same time preventing creepagejof bottles rough the inspector at speedslbelow that necessary tolrnaintain proper inspection. I p

Another problem results from the backaccumul'ation of. bottles at the tiller which, as

' keep. the filler supplied with a constant supply of bottles. Such back-accumulation, however, if

not properly controlledwill throttle'the inspector outfeed causing theexcessive-bottle prcssuretcreated thereat to seelt'.r elict by the ejectioncf clean bottles -frornthe: in-

I spector in a manner normally reserved .for the reiection of dirty bottles. This'prohlem of back-accumulation critical the closer the inspector On the other hand, it will be desirable and often Furthermore, due to I stated above,.is desirable FIG. 4;

diflicult problems. One major bottles through theinspector. The'inspeotor employs a rotatable indexingmember such as a backrsccumulation control tinned vtravel to the filler.

' cation Serial No. 808,172, tiled April 22, 11959, e Patent No. 3,081,666, and assigned to the assignee'oi and filler in close proximity.

inspector and filler are FIG. 4; 7

bottles in a linear path -l will depend largely on the bottles .t o-be handled.

.outfeed of the turret through essential that the amount of II to a minimum. Eurtherrnore, by locating inspector a single operator, can more easily and effectively handle both machines. I With-the above considerations in prevent throttling the inspector outfeed, even where Other objects and advantages 'will bopointedout' in,

or beiapparent from the specification and-claims, as; will arrangement embodying the present invention; I

FIG. 2. is a side elevation view of the inFIG. 1;

FIG. 3 is a sectional viewtaken along line 3-.3 of FIG. 2; r i FIG. 4 is a partialside elevation View of the inspector showing the drive and control apparatus therefor;

FIG. 5 is a sectional view taken'along line 5-5 of apparatus shown .FlG.s6 is a sectional view taken along line \6'--.6'of FIGS. 7 and 8 are fragmentary top plan views of the inspector and conveyor arrangement'showing the inieed control'apparatus for the inspector drive means;

FIG. 9 is a fragmentary elevation view taken along line 9- -940fFIG17; I

FIGS. l0 and 13 are fragmentary top plan views of the inspector and conveyor arrangement showing the apparatus at the entic d .of the inspector;

. FIG. 11 is otFIG.10;

FIG. 12 is a partial side elevationview' taken along line 1%12of FIG. 10; and v 1 7 FIG. 14 is a partially schematic layout of, the hold pressure arrangement for operating the turret brake under the control oi. the infeed andbaclg-accumulation oontrolm'eans.

' Referring now to the drawings in detail, FIG, 1 shows a conveyor 10 adapted to carry bottles or other com tainers from left to'rig'ht from a bottle washer (not shown) to an inspection apparatus ra-1am then'from the inspector to a bottle filler (not show'n), Conveyor 10" is provided with guide rails a sectional view taken along line 11- 41 10 n o inspe o ,2 Inspector 12 includes a rotatablein'dexing member or turret 16 designed to carry bottles in an arcuate path from the conveyor through an inspection-station ill-and thenback onto the conveyor (if not rejected) for con- The specific des gn of turret si an a a In the disclofi d. embodiment, turret 16 is comprised of a .pair'pofinterconnected star'- 26, respectively, designed-to engage the neck and base of-a bottle and carry it in an arcuate path through the inspection stationts. I

The dirty bottles are ejected from the conveyor at the rotating reject table I II I ratus employed for detecting dirty bottlos;may he of any suitable type such as that disclosed .in copending applithis application.

' Turret 161 is-rnounted on a vertical drive shaft 32 driven by a drive arrangement which includes a constant speed motor 34 mounted beneath the turret Aland floor spaceutilized b k pt rod, :1 second important ohie tive of this invention-is to provide'a mea s for automatically controlling back-ammulution at the-filler -to thus located relatively close; together.

embodiment shown in I 14 adnptedto direct the .flow of 1 p a h a reject exit 218 onto a. 30. The particular inspection appacarried to the pointed. out previously,

gagement with shaft 32 .by H p v drive arrangement of; conventional design-comprising as 40 and timing assembly 46 (FIG.

' by motor 34 can Clutch so adapted to drive shaft 32in a clockwise direction- (as;

viewed in FIG. 1). r l V.

fedby 'a complement of bottles" The turret isnormally on the turret, the turret will engage properly and smoothly with the incoming flow of bottles. If, for' any reason, the bottle spacing varies from that ofithe notche on the turret, synchronism-betwecn thetwo will be lost'and: clashing or jamming wilLresultf inspector byconveyor -10. The turret to the turret tends to that "of gear, teeth 68 and prevent a l constant'speed drive for Variousarrangements and designs have been; tried in V n .etfort to provide 7 chronism and at the same time provide the =proper bottle flow for inspection. made to operate'fieewhcelingfias a'fimction oiithe turning elfort imparted by the how of bottles on the-conveyor,

bottles were present the turret would not turn and there coming bottle without dangerof jammingor failureto properly-mesh; An ment, however, is the factthat the-turning often required by the turret is not'at all times consistent-with the turning effort imparted by the how of bottles 'on the conveyor due to the fact thatthe momentum of bottle flow, as is not constant,- tlius giving rise to avariable pressure at the turret'rcsultingina variable turning effort or torque imparted to the turret. T'lhe problem is furthercomplicated bythe fact that the in- .spec tion apparatus 12. will-generally require bottle trans-V lation' speeds of a specific minimumvalue'belowwhich' i the inspcctor'will not operate properly, Thus; the .ve'ry' "slow bottle speeds sometimes encounteredih a pure imewheeling arrangement are objectionable in thistimproper inspection results. V 7 p 1 #To overcome the problems described'above,.a drive and control arrangement motor drive adapted I 'in addition to that developed by the mcomin'g-fbottles; As shownin FIGS. 5 and 6, such supplementaltbrque is provided by a constant speed motor 34jin driving;.enmeans of 'a variable speed freely rotatably rnounted on shaft 32 by ball bearing ,5). T he speed when actuated will movejtlie motor clutch arrangement-50 (FIG. 5) mounted on shaft 32. includes a hub 52 keyed to shaft 32 and-an adjustable collar 54 threaded0n the. hub. Rotation of collar 54 on hub 52 will vary the force with which-pressure plate 56:.is urged into-contact with clutcli face 58 on gear 44 by spring member 60.

Thus it is seen that'the total torque imparted to shaft 32 will be the sum of the substantiallyconstant torque value providedby motor 34 plus the varying torque pro-.

6) is provided. Such anangementincludes an arm 64 keyed to shaft 32- and a system which will maintain ayn 'Iheoretically,- if thetu rret were .v w man's am is driven by motor 34 is controlled .by means-of rod speed rugs situation a speed limiting pawl each bottle wouldscelr its pocket in thetuljret andifno inherentlimitation in such an arrange? auras Q havinga sp i g biased-pawl 6:6 mouniedbn-the end thereof for unidirectional engagement withratchet teeth 68 bra-timing gear 44.- As stated previously,inotor 34mm at 'a 'constant speed and will drive timing gear 44 at a constant speed; Thus,

if the bottle hiflowjpressure at the turret reaches. a value and ratchet arrangement 62' elfcctively cooperate to limit the maximum speedof turret 16.. I

Y To,'insure propersynchronization between bottle flow andturret rotation an intc'd control arrangementfohis provid'edj ,(EIGS..- 7, 8 and 1 4).- Suchalfrangement includes'a normally open fluid valve 70 and a bottle sensing actuator rnemb'eri72 mounted-upstream-ofinspector 12. Actuator arm 72 is designed to sense the presence or absence of incoming bottles'on the, conveyor. As shown in FIGS. 7, -8and Mfin the absenceor bottles atarm 72 on' the conveyor; valve 70 will open allowing'fiuid pressure tofiQwjrom-supply conduit 74 throughconduit'lfi, valve70, conduits 78-and 80 to a fluid pressure'respon- 'sive; brake 82 mounted 'on'turret shaft 32. Brake 82 (FIG. 5) is comprised of an cxpandableboot'lid fixedly mounted with respect to shaft 32 and adapted-when pressurized to force a pressure band 86 .into Contact with a hood member 88 keyed to shaft 32 to therebyapply a brakingtorce toftheshafl.

Thus, as shown in FIG. 7, witha: steady liowofbotis provided which includes a to provide a supplemental torque new complement.--oi bottles the effective diameter oi pulleyfi'fi, amount of torque imparted to :tlhufltfBZ be set by an adjustable torque limiting. 5

motor will tend to keeplthe turret i q {motor '34 and the for any reason...

t duringlthe stoppage." torque limiting clutch I proper operation-of infced Tcloscd andbraKe'BZ will he deenergized allowing shaftj32 to be driven freely'by thecombined torque supplied by bottleinilow pressure at the turret. If, I

an interruption in bottle flow occurs, valve 70 will open when the last boltle before the gap passes-arm 12 (FIG. 8); The opening of valve 70 will 'set brake 82 causing the turret to stop 'and be held stationary Ill'llillhe valve'is closed by a new complement ofbottles arriving atlarm 72 .on' conveyor 10. It is noted thatjwhenjhe brakeisset .(FIG. 8) thenotchcs o'f; turret I6 andthe co nveyor'betweenarm 72 and inspection station 1am f ully occupied 'by. bottles, -.Thus, when a arrives at arm 72'to close {start 11p because thejimre't was. never-devoid of bottles '50 be:-adjustedto provide the lthebottie pressureatithelturret decrease steadily as the gap approaches arm '-the torque provided-by motor 34. will 'besufficient to keep the turret rotating until the gap reaches arm 72 causing'the brake to set.- This is important since if the turret were to stop-before arm 72'is released (by a gap inbottleflow) there would be a tendency for the bottles intheturretitocreep slowlypa'st inspection station 18 resulting in improper inspection of thosebottles which pass at below the-minimum required speed.

inally, it'should'be'noted that upon start-upof turret .celerationr I As stated previously, 12 between. the-bottle cleaner and the :fi'ller' screw of the tiller creates a problem 'withrespect to the normal bacle II'he turning elfor't imparted to" 2 gear 4.4 in conjunction with pawl w szlthere is noproblcrp' of synchronization between bottles and turret upon-:turret v5t) belt 42 whichjdrivesja timing; gear 44' lnathisregardjitis important that controlvalve 70. It .will be I 7 appreciated thatcwhen a gap insinieed'bottle flow occurs 12. Clutch 50-is set sothat,

the interposition of inspector accumulation of bottles at the filler. If bottles are allowed to accumulate from the filler back to the reject exit 28 at the inspector outfeed, clean bottles will be forced through exit 28 onto reject table 30. As explained pre viously, the rated speed of bottle flow through the inspector is dependent on the turning effort developed by the flow of bottles themselves plus the torque supplied by the motor 34. By providing an automatically controlled means 89 for reducing the speed of the turret, the rate of flow can be slowed down when necessary to prevent excessive baclt-accumulation.

Such automatic control means 89 in shown in FIGS. 10. ll, 12, 13 and 14 and includes a modulating control valve 90 mounted at the inspector outfeed. Valve 90 is normally closed and is modulated between open and closed positions by an elongated modulating arm 92 pivotally mounted adjacent conveyor as shown in FIGS. 10 and 13. Arm 92 is actuated in response to back-accumulation by means of flexible bottle guide members 94 and 96 resiliently mounted on either side of conveyor 10 adjacent arm 92 by springs 98, 100 and 102 (FIG. 13).

As a natural characteristic of back-accumulation the bottles will assume a staggered or ofiset flow pattern in contrast with the normal linear flow pattern of a freely flowing line of bottl This staggered or oflset pattern will tend to cause the bottles to fill the space between guide members 94, 96 causing member 94 to bulge outwardly and thereby react on modulating arm 92 as shown in FIG. 13. Actuation of arm 92 will cause modulating control valve 90 to start to open which in turn will allow air to flow from supply conduit 74 through valve 90 and then through conduits 78 and 80 to brake 82. The introduction of fluid pressure to boot 84 of brake 82 will force brake band 86 into contact with hood 88 producing a brak- 3 shaft 32. Such braking action will slow down the rotation of turret 16 to thereby restrict the flow of battles to the conveyor downstream of the inspector and thus relieve back-accumulation. As shown in FIG. 10, as back-accumulation begins, arm 92 will be actuated to open valve 90 which in turn will increase fluid pressure in expandable boot M to apply a braking action to shaft 32. As back-accumulation increases in severity (FIG. 13), the braking action at shaft 32 will be correspondingly increased until valve 90 is completely opened causing the brake to completely stop turret 16. It should be noted at this point that when turret speed is slowed by brake 82 in response to back-accumulation, timing gear 44 on shaft 32 will continue to be driven at a constant speed by motor 34. The diiferenoe in speed between gear 44 and shaft 32 will result in slippage at clutch means 50.

When the bottle pressure due to back-accumulation is sufliciently relieved to allow the bottles to reassume a perfectly linear flow pattern, guide member 94 straightens out, arm 92 is returned by spring 104, and valve 90 is again closed to deenergize brake 82 and again allow turret 16 to resume its normal speed in response to the torque supplied by motor 34 and the incoming bottle flow.

In the preferred embodiment described above, springs 98 and 100 of member 94 are not as strong as spring 102 of member 96. Thus, member 94 will be the first to bulge outwardly when back-accumulation occurs. it should be noted at this point that only a single flexible guide member 94 is required to sense back-accumulation and actuate arm 92. The second guide member 96 is provided to allow for a greater degree of back-accumulation than would otherwise be the case.

Operation A typical operation of the above described inspector drive means is as follows. I

With a steady flow of bottles from the washer to inspector 12 on conveyor 10, fluid valve 70 will be held closed by arm 72 to maintain brake 82 deenergized and ing action at allow turret 16 to be driven freely by the combined torque supplied by motor 34 and the bottle inflow pressure at the turret.

The maximum amount of torque imparted to shaft 32 by motor 34 can be set by an adjustable torque limiting clutch 50. If, for any reason such as a bottle gap, bottle inflow pressure drops off the motor will tend to keep the turret turning at a suflicient minimum speed to maintain proper operation of inspector 12. On the other hand to control maximum turret speed in a situation where bottle inflow pressure is high, a speed limiting pawl and ratchet arrangement 62 is provided.

If, for any reason, an interruption in bottle flow occurs, valve 70 will open when the last bottle before the gap passes arm 72. The opening of valve 70 will set brake 82 causing the turret to stop and be held stationary until the valve is again closed by a new complement of bottles arriving at arm 72.

The automatically controlled means for reducing turret speed in response to back-accumulation at the in spector outfeed includes a modulating control valve actuated by a modulating arm 92 pivotally mounted adjacent a resiliently flexible guide rail member 94. The staggered or offset pattern of bottles which results from a back-accumulation will tend to cause the bottles to fill the area adjacent member 94 causing such member to bulge outwardly against arm 92. Movement of arm 92 will cause an increasingly greater fluid pressure to be exerted at brake 82 which in turn will apply a corresponding braking action to the turret. Thus, as the severity of back-accumulation increases at arm 92 the amount of braking action at the turret shaft will also be increased until the turret is completely stopped. As back-accumulation is reduced the braking action will fall off allowing the turret to resume normal speed.

Although but one embodiment of the present invention has been illustrated and described, it will be appareat to those skilled in the art that various changes and modifications may be made therein without departing from the spirit of the invention or from the scope of the appended claims.

I claim:

1. Drive and control apparatus for the turret of a bottle inspector adapted to handle a flow of bottles on a conveyor comprising, a constant speed drive means for the turret, brake means for applying a braking action to said turret, infeed control means for said brake means adapted to sense a gap in the flow of bottles on the conveyor upstream of the inspector and to energize the brake to stop the turret when such a gap occurs, and slip clutch means between said drive means and the turret to permit said drive means to run continuously even during periods when said brake means is applied.

2. Drive and control apparatus according to claim 1 in which said slip clutch means is adjustable and is set so that the torque transmitted thereby from said constaut speed drive means to the turret is sufficient to maintain turret rotation until a gap in the bottle flow is sensed by said infeed control means.

3. Drive and control apparatus according to claim 1 in which said infeed control means includes an infeed bottle sensing member movably mounted upstream of the turret and a fluid pressure valve adapted for actuation by said infeed sensing member, said fluid pressure valve adapted when actuated to energize and deeuergize said brake means.

4. Drive and control apparatus for the turret of a bottle inspector adapted to handle a flow of bottles on a conveyor comprising, a constant speed drive means for the turret, brake means for applying a braking action to said turret, infeed control means for said bralre means adapted to sense a gap in the flow of bottles on the conveyor upstream of the inspector and to energize the brake to stop the turret when such a gap occurs, a maximum speed control means for said turret adapted to prevent said turret from exceeding the speed of said drive means, and slip clutch means between said drive means and the turret to permit said drive means to run continuously even during periods when said brake means is applied.

5. Drive and control apparatus according to claim 4 in which said speed control means includes a timing gear freely rotatably mounted with respect to the turret, and an arm member operatively connected to said turret and in unidirectional engagement with said timing gear.

6. Drive and control apparatus according to claim 5 in which said infeed control means includes an infeed bottle sensing member movably mounted upstream of the turret and a fluid pressure valve adapted for actuating by said infeed sensing member, said fluid pressure valve adapted when actuated to energize and deenergize said brake means.

7. Drive and control apparatus for the turret of a bottle inspector adapted to handle a flow of bottles on a conveyor comprising, a constant speed drive means for the turret, brake means for applying a braking action to said turret, infeed control means for said brake means adapted to sense a gap in the flow of bottles on the conveyor upstream of the inspector and to energize the brake to stop the turret when such a gap occurs, a maximum speed control means for said turret adapted to prevent said turret firom exceeding the speed of said drive means, back-accumulation control means operative in response to back-accumulation at the inspector outfeed, said backaccumulation control means adapted to modulate the braking action exerted on the turret by said brake means to thereby modulate the speed of said turret in accordance with the degree of back-accumulation, and slip clutch means between said drive means and the turret to permit said drive means to run continuously even during periods when said brake means is applied.

8. Drive and control apparatus according to claim 7 in which said back-accumulation control means includes a modulating arm adapted to sense back-accumulation of bottles on the conveyor downstream of the turret and a modulating control instrumentality actuated by said arm and adapted to modulate the turret speed in response to actuation by said modulating arm.

9. Drive and control apparatus according to claim 8 in which said bacleaccumulation control means further includes a bottle guide member movably mounted adjacent the conveyor and adapted to sense a staggered or offset flow pattern of bottles on the conveyor.

10. Drive and control apparatus for the turret of a bottle inspector adapted to handle a flow of bottles on a conveyor comprising, drive means for the turret, and

back-accumulation control means operative in response to back-accumulation at the inspector outfeed and adapted to modulate the speed of said turret to thereby reduce bottle throughput at the inspector upon the occurrence of such back-accumulation, said back-accumulation control means including a modulating arm adapted to sense back-accumulation of bottles on the conveyor downstream of the turret and a modulating control instrumentality actuated by said arm and adapted to modulate turret speed in response to actuation by said modulating arm, said bacloaccumulation control means further including a bottle guide member movably mounted adjacent the conveyor and adapted to sense a staggered or otfset flow pattern of bottles on the conveyor, said bottle guide member adapted to actuate said modulating arm when a staggered or offset flow pattern of bottles on the conveyor occurs, said back-accumulation control means further including a brake means for said turret under control of said control instrumentality and adapted to vary the speed of the turret in response to movement of said bottle guide member and said modulating arm.

11. Drive and control apparatus for the turret of a bottle inspector adapted to handle a flow of bottles on a conveyor comprising, a constant speed drive means for the turret, and maximum speed control means for said turret adapted to prevent said turret from exceeding the speed of said constant speed drive means, said maximum speed control means including a timing gear having ratchet teeth thereon freely rotatably mounted with respect to the turret, an arm member operatively connected to said turret, and a pawl member pivotally mounted on said arm member, said pawl member adapted for unidirectional engagement with said ratchet teeth on said timing gear.

12. Drive and control apparatus for the turret of a bottle inspector adapted to handle a flow of bottles on a conveyor comprising, a constant speed drive means for the turret, brake means for applying a braking action to said turret, infeed control means for said brake means adapted to sense a gap in the flow of bottles on the conveyor upstream of the inspector and to energize the brake to stop the turret when such a gap occurs, and a maximum speed control means for said turret adapted to prevent said turret for exceeding the speed of said drive means.

UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 3, 152 478 October 20, 1964 George L. N. Meyer ified that error appears in the above numbered pat- It is hereby cert on and that the said Letters Patent should read as ent. reqliring carrecti corrected below.

line 42, for "for" read from Column 8,

Signed and sealed this 2nd day of February (SEAL) Atteet:

EDWARD J. BRENNER 

1. DRIVE AND CONTROL APPARATUS FOR THE TURRET OF A BOTTLE INSPECTOR ADAPTED TO HANDLE A FLOW OF BOTTLES ON A CONVEYOR COMPRISING, A CONSTANT SPEED DRIVE MEANS FOR THE TURRET, BRAKE MEANS FOR APPLYING A BRAKING ACTION TO SAID TURRET, INFEED CONTROL MEANS FOR SAID BRAKE MEANS ADAPTED TO SENSE A GAP IN THE FLOW OF BOTTLES ON THE CON- 